THE EFFECT OF PHONOLOGICAL ABILITY ON MATH IS …
Transcript of THE EFFECT OF PHONOLOGICAL ABILITY ON MATH IS …
Yulia V. Kuzmina, Diana N. Kaiky,
Alina E. Ivanova
THE EFFECT OF PHONOLOGICAL
ABILITY ON MATH IS
MODULATED BY
SOCIOECONOMIC STATUS IN
ELEMENTARY SCHOOL
BASIC RESEARCH PROGRAM
WORKING PAPERS
SERIES: PSYCHOLOGY
WP BRP 104/PSY/2018
This Working Paper is an output of a research project implemented at the National Research
University Higher School of Economics (HSE). Any opinions or claims contained in this
Working Paper do not necessarily reflect the views of HSE
Yulia V. Kuzmina1, Diana N. Kaiky
2,
Alina E. Ivanova3
THE EFFECT OF PHONOLOGICAL ABILITY ON MATH
IS MODULATED BY SOCIOECONOMIC STATUS IN
ELEMENTARY SCHOOL
Math achievement is affected by social factors such as socioeconomic status (SES) and
domain-general cognitive factors such as phonological ability. Little is known how the effects of
cognitive factors change depending on social factors during development. This study focuses on
the estimation of the effect of phonological ability on math achievement during the first year of
schooling and testing the hypothesis that this effect varied depending on students SES. To
achieve our aims we used two-wave longitudinal study which was conducted on large sample of
first-graders (N= 2,948) in the Tatar Republic (Russia). Participants were assessed twice, at the
beginning and at the end of the first grade (mean age was 7.3 years at Time 1). The item
response theory (IRT) scaling procedure was used to estimate individual scores in math, number
identification, phonology and reading. In order to estimate the effect of phonological ability and
SES on math performance, mixed-effect longitudinal models were applied. The results revealed
that phonological ability had a significant positive effect on math achievement even when
reading achievement, number identification and SES were controlled for. Among SES
dimensions only maternal education had an effect on math achievement and its improvement.
The effect of phonological ability was higher for students with a larger number of books at home
and who used more than one language at home.
Keywords: iPIPS; math achievement; phonological ability; socioeconomic status; moderators
JEL Classification: Z
1 Center of Education Quality Monitoring, Institute of Education, National Research University
Higher School of Economics, Research Fellow, e-mail ([email protected]) 2 Center of Education Quality Monitoring, Institute of Education, National Research University
Higher School of Economics, Research Assistant, e-mail ([email protected]) 3 Center of Education Quality Monitoring, Institute of Education, National Research University
Higher School of Economics, Research Fellow, e-mail ([email protected])
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Many factors contribute to individual differences in math achievement. Both the
cognitive and social predictors of math development have been extensively discussed in the
literature. Sociologists and policymakers mostly focused on the relationship between math
achievement and socioeconomic status (SES), whereas cognitive and educational psychologists
focused on the cognitive predictors of math achievement. To optimize mathematical, educational
and instructional practices, it is necessary to understand how these factors relate to and interact
with each other during development.
SES is supposed to be one of the strongest predictors of academic achievement, both in
reading and math (e.g. OECD, 2010; Sirin, 2005). The advantages of children from families with
high SES emerge before the start of schooling; these differences might remain or expand through
school years (Bradley & Corwyn, 2002; Caro, McDonald, & Willms, 2009). There is plenty of
evidence that SES is predictive for multiple components of reading skills and development,
including decoding, print knowledge, and comprehension (Bowey, 1995; Hecht et al., 2000;
Noble et al., 2006; Molfese, Modglin, & Molfese, 2003). SES also affected early precursors of
math achievement such as number sense and number competence (e.g. Jordan et al., 2006;
Jordan & Levine, 2009).
One possible mechanism explaining this is that SES may affect cognitive functions that
correlate with later academic achievement. There is plenty of evidence that low family SES
impairs working memory capacity, executive function, intelligence and phonological ability
(e.g., Ardila et al., 2005; Farah et al., 2006; Engel et al., 2008; Hackman et al., 2015). That may
lead to a further decrease in academic achievement. Particularly, it was demonstrated that the
effect of SES on math achievement might be mediated by Approximate Number Sense (ANS)
and time detection capacity (Valle-Lisboa et al., 2016). The effect of SES on reading
achievement was also mediated by phonological abilities (Bowey, 1995; Zhang et al., 2013).
There is evidence that phonological ability also has a significant effect on math
achievement. Phonological ability refers to the sensitivity for the sounds of their language and
the capacity to use these sounds to decode linguistic information, the ability to process and
understand the sound structure of oral language (Wagner & Torgesen, 1987). The effect of
phonological ability on math was more prominent for math performance that involved fact
retrieval strategies (De Smedt et al., 2010; Pospoel et al., 2017).
Neuroimaging studies have also confirmed a close relationship between phonological
processing and arithmetic fact retrieval (Prado et al., 2011; Simon, Mangin, Cohen, Le Bihan, &
Dehaene, 2002). In particular, it was shown that arithmetic problem solving involved brain
regions associated with language processing (Arsalidou & Taylor, 2011; Pollack & Ashby, 2018;
Prado et al., 2014). Earlier studies demonstrated the significant activation of the brain areas
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involved in language processing during single-digit multiplication and addition operations
compared to subtraction problems (Simon et al., 2002; Prado et al., 2011).
Some studies have demonstrated that a deficit of phonological ability can be one of the
factors of dyscalculia (DeSmedt & Boets, 2010; Vukovic & Siegel, 2010). Vanbinst, Ghesquière
and De Smedt (2014) demonstrated that children with dyscalculia, who also showed persistent
difficulties in arithmetic fact retrieval, performed significantly worse on all dimensions of
phonological processing, and these differences were significant even after intelligence, working
memory capacity or reading abilities were controlled for. Although it is unlikely that a
phonological deficit is the core deficit for children with dyscalculia (e.g., Landerl, Bevan, &
Butterworth, 2004), the phonological deficit could be an additional risk factor for developmental
math difficulties (De Smedt, 2018).
On the other hand, some studies failed to find a significant relations between
phonological and math ability (e.g., de Jong & van der Leij, 1999; Passolunghi, Vercelloni, &
Schadee, 2007). In particular, studies have shown that children with both math and reading
difficulties usually demonstrated a deficit in phonological processing, while children with only
math difficulties often did not show phonological impairments (e.g., Geary, 1993; Moll, Gobel,
& Snowling, 2015; Rourke & Conway, 1997). In line with these results, phonological abilities
were found to be unique predictors of reading performance but not of math performance
(Bradley & Bryant, 1983; Passolunghi, Vercelloni, & Schadee, 2007).
SES can modulate relations between certain types of cognitive predictors and academic
achievement (e.g. Demir, Prado, & Booth, 2015; Noble, Farah, &McCandliss, 2006).
Particularly, it has been demonstrated that SES moderates the relation between phonological
ability and decoding skills for reading (Noble, Farah, & McCandliss, 2006). It has also been
shown that SES moderates the relation between math gains and brain activation in regions
related to verbal numerical representations and spatial representations. Activity in the brain
regions associated with verbal activity during math problem solving was higher for participants
with higher SES whereas activation of regions associated with spatial representations was higher
for low SES participants (Demir, Prado, & Booth, 2015; Demir-Lira, Prado, & Booth, 2016).
This means that children from high SES families rely more on verbal processing during math
activities and that SES-related differences in mathematics are larger for the verbal aspects of
mathematics (Jordan & Levine, 2009).
Despite a large body of research regarding the relationship between phonological ability
and math, and the effect of SES on math achievement, little is known about how SES modulates
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the effect of phonological ability on math achievement and math progress. Previous studies did
not focus on how the effect of phonological ability varies for children with different SES.
Meanwhile, this issue might be important for planning remedial programs for children with
mathematical difficulties or for the design of developmental programs for children from low SES
families.
Current study
The current study has three main goals. The first goal is to estimate the effect of
phonological ability on math performance, controlling for reading achievement and number
identification skills in the first year of schooling. Although numerous studies investigated the
relationship between phonological ability and math, they had several limitations. First of all,
most studies were conducted on small samples, which could lead to biased estimations of the
effects. Another restriction is related to the cross-sectional design of previous studies which
limited their capacity to estimate the effect of phonological ability on progress in math. Our
study overcomes these restrictions by using a large sample size and longitudinal two-wave
design. We used mixed-effect analysis in order to estimate the effect of phonological ability on
math achievement and math progress.
The second goal of our study is to estimate the effect of different SES measures on math
achievement and improvement during the first year of schooling. We used two indicators of
family SES: maternal education and the number of books at home. Previous studies
demonstrated that different indicators of SES had different effects on academic achievement and
it is necessary to take into account potential variation in these effects (Sirin, 2005).
Previous studies demonstrated that parental education was a powerful predictor of
academic achievement (Sirin, 2005) and that its effect was independent of the effects of family
income. Several studies also showed that the number of books at home was a reliable indicator
of family cultural and educational status which also reflected parental investment in child
development (Brunello, Weber, & Weiss, 2016). The number of books at home had a positive
effect on students achievement even when parental education and income were controlled for
(Brunello, Weber, & Weiss, 2016; Evans et al., 2010).
We also include language at home as a potential predictor of math achievement. As we
obtained data for our study in the Tatar Republic in Russia, some participants used two
languages at home (Tatar and Russian) or only Tatar whereas instruction in elementary school
was in Russian for our sample. That allowed us to estimate the effect of using other languages at
home on academic achievement. Language at home was supposed to be a significant predictor of
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academic achievement although in some cases this effect might be explained by SES differences
(Chiu & Xihua, 2008; Kennedy & Park, 1994).
The third goal of our study is to estimate whether the effect of phonological ability is
modulated by student SES and language at home. We hypothesize that children from high SES
families tend to more actively involve verbal processing during math problem solving, hence the
effect of phonological ability is larger for children with high SES.
We have several research questions regarding our aims:
1) Does the phonological ability affect math achievement during the first year of
schooling?
2) Do children with high phonological ability demonstrate better progress in math during
the first year of schooling?
3) Does the progress in math during the first year of schooling vary for students depending
on their SES and language at home?
4) Does the effect of phonological ability vary for students with different SES?
Method
Participants
This study was conducted in Russia (in the Tatar Republic) during the 2017-2018
academic year. The initial sample of 3,450 first-graders was assessed in October 2017, at the
beginning of the first year of schooling (Time 1), and the second stage of the assessment was
conducted in May 2018, at the end the first school year (Time 2). In the resulting sample for
analysis only children who participated in both waves and whose parents gave information about
SES were used. The final sample consisted of 2,948 first-graders (49% were girls). The mean
age was 7.3 years at the beginning of the school year and 7.8 years at the end.
The parents of the respondents gave their informed consent before the survey. The data
were collected anonymously. The Institutional Review Board at the Higher School of Economics
approved the study, and the data were collected according to the guidelines and principles for
human research subjects.
Instruments and procedure
In order to estimate math and reading performance, and phonological ability the Russian
version of iPIPS (the international Performance Indicators in Primary Schools) was used. iPIPS
is based on the Performance Indicators in Primary Schools (PIPS) monitoring system, developed
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by the Centre for Education and Monitoring at Durham University in the UK (Tymms, 1999;
Tymms, Merrell, & Wildy, 2015). The Russian version of the iPIPS assessment was developed
from 2013 to 2015 (Ivanova et al., 2016).
Children were assessed on a one-on-one basis by trained testers using computer-assisted
software. The assessment, which lasted approximately 15 to 20 minutes, occurred at school and
in a separate, quiet room. Each child sat with a tester in front of a computer.
The computerized software-guided test employed a dynamic adaptation algorithm, that is,
a sequence of items with stopping rules. The items within each section were arranged in order of
increasing difficulty, children started with easy items and moved on to progressively more
difficult ones. When the child made three consecutive or four cumulative errors in a section, the
assessment of that section stopped and the child proceeded to the next section.
Measures
During two assessment cycles, the same sample of children were presented with the same
set of items. In order to examine the achievement level of students over time, we applied the IRT
technique, specifically, anchor item equating, using the dichotomous Rasch model (Kolen,
Brennan, 2004). Thus, the items were equated such that a continuous scale was used to assess
student development from Time 1 to Time 2.
Outcomes
Math performance
For the estimation of math achievement a total of 19 tasks were presented. These tasks
included word-based problem-solving tasks and two-digit arithmetic tasks. The scale was
unidimensional, with items highly correlated, and test reliability (Cronbach’s alpha) varied from
0.8 to 0.9 for Time 1 and Time 2.
Predictors
Phonological ability
We used two types of tasks to assess phonological abilities: rhyming tasks and
word/pseudo-word repetition tasks. For the rhyming task, the child had to select the word that
rhymed with a target word from three options. In total, five target words were presented. As
incorporated in the software, each word was illustrated with a picture and pronounced by a
professional narrator. In the word/pseudo-word repetition task, the child was asked to repeat a
word or pseudo-word (for example, “frigliyaga” (pseudoword) and “stop” (word)) immediately
after hearing it pronounced by the assessment software. There were five items for word
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repetition and three items for pseudo-word repetition. The reliability was 0.7 at Time 1 and 0.9 at
Time 2 assessment.
Number identification
The number-identification tasks included single-, two- and three-digit numbers. The child
was asked to name numbers that were presented visually. A total of nine numbers were
presented. The scale was unidimensional, with items highly correlated, and test reliability
(Cronbach’s alpha) varied from 0.8 to 0.9 for Time 1 and Time 2.
Reading performance
The reading performance scale was constructed based on tasks that included letter
recognition, word decoding and reading comprehension. First, for letter recognition estimation,
children were asked to name letters presented on the screen, eight letters in total. Tasks for the
estimation of word decoding skills included fluent printed word recognition and the reading
aloud of a short simple story. The words were of high frequency. For the words and the story,
each word recognized and read correctly was counted as a correct answer. In the story reading
task, the child had to read a short story of 34 words divided into three parts accompanied by
related pictures. If the child was able to read half of the words in each part correctly, the item
was scored as correct.
The reading comprehension task included two more difficult texts where the child was
required to read a passage and, at certain points, to select one word from a choice of three that fit
the story best (in total, 36 choices were scored). The reliability of the reading scale was higher
than 0.9 for both Time 1 and Time 2.
SES measures
The information about family SES was obtained from parental questionnaires. We used two
indicators of family SES: maternal education (1 – mother has higher education; 0 – mother has
no higher education); number of books at home (1 – family has more than 100 books at home; 0
– family has less than 100 books at home). We also included variable “language at home” (1 –
family uses only Russian language at home; 0 – family uses both Russian and another language
at home).
Statistical approach
In order to answer our research questions, we used mixed-effect models in which Time 1
and Time 2 measures were considered as nested in individuals. These models allow us to
estimate the effect of predictors on outcomes and time changes in outcomes. Mixed-effect
models also estimate between-individuals and within-individual variance (random effect). Using
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mixed-effect models enabled us to estimate the effects of both time-varying and time-invariant
predictors, so we were able to estimate both the effect of phonological ability on math
achievement and the effect of SES.
We tested several mixed-effect regression models for math achievement as the outcome:
1) Model 1. In this model a time variable was included. The coefficient of the time
variable demonstrated the time changes of math achievement from Time 1 to Time 2.
2) Model 2. In this model some time-variant and time-invariant predictors were added.
In order to estimate the effect of phonological ability we added phonological ability
as a predictor. The coefficient of this variable reflected how math achievement
changed when phonological ability increased by 1 logit. We also added reading
achievement and number identification as predictors in order to get more reliable
estimations of the effect of phonological ability. We also added SES measures and
gender (1 = female) as a predictors.
3) Model 3. In order to estimate the effect of phonological ability on progress in math,
we added interaction between the time variable and phonological ability. The
coefficient of the interaction term reflected the differences in progress in math
progress for students with different phonological abilities.
4) Models 4–6. In order to estimate how math progress varied for students with different
SES backgrounds, we included interaction terms between different dimensions of
SES, language at home and the time variable. The significance of these terms
indicated that time changes significantly varied for students with different SES.
Model 4 included interaction between maternal education and the time variable.
Model 5 included interaction between the number of books at home and the time
variable and Model 6 included interaction between language at home and time.
5) Models 7–9. In order to estimate how the effect of phonological ability varied
depending on SES and language at home, we included interaction terms in
consecutive models: interaction between maternal education and phonological ability
(Model 7), interaction between the number of books at home and phonological ability
(Model 8), interaction between language at home and phonological ability (Model 9).
The significance of interaction terms can be interpreted as the significance of the
differences in effect of phonological ability for students with different SES or
language at home.
We compared the models with interaction with the model without interaction (Model 2)
using the likelihood ratio test (LR test). This test indicated that the model with
interactions fitted the data better than the model without interaction.
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Results
Descriptive statistics
We examined math and reading achievement, phonological ability and number identification at
Time 1 and Time 2.
Table 1
Descriptive statistics for math and reading achievement, phonological ability and number
identification
Variables Mean
(in logits)
SD Min Max
Math achievement at Time 1 -1.32 2.22 -6.08 5.91
Math achievement at Time 2 0.91 2.13 -5.03 5.92
Phonological ability at Time 1 0.82 1.46 -5.24 4.36
Phonological ability at Time 2 1.97 1.79 -5.22 4.36
Reading achievement at Time 1 0.04 2.58 -7.01 6.89
Reading achievement at Time 2 2.47 2.13 -7.20 6.91
Number identification at Time 1 2.08 4.79 -9.08 8.34
Number identification at Time 2 5.19 3.72 -6.27 8.35
Descriptive statistics revealed that all measures increased from Time 1 to Time 2.
Descriptive statistics for SES measures are presented at Table 2.
Table 2
Descriptive statistics for SES measures
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Variables Values %
Mother’s education 0 – no higher education 48%
1 – higher education 52%
Number of books at home 0 – less than 100 books at home 88%
1 – more than 100 books at home 12%
Language at home 0 – not only Russian language at
home
16%
1 – Russian language at home 84%
The results of the mixed-effect analysis
The results of the mixed-effect analysis are shown in Table 3.
Table 3
The results of mixed-effect analysis for math achievement as outcome
Variables Model 1 Model 2 Model 3
Constant -1.32*** (0.04) -1.85*** (0.07) -1.90*** (0.08)
Time 2.23*** (0.04) 1.04*** (0.04) 1.17*** (0.06)
Phonological ability 0.19*** (0.02) 0.25*** (0.02)
Reading achievement 0.16*** (0.01) 0.15*** (0.01)
Number identification 0.19*** (0.01) 0.19*** (0.01)
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Mother has higher
education
0.30*** (0.05) 0.31*** (0.05)
Number of books at home 0.12 (0.08) 0.11 (0.08)
Only Russian language at
home
-0.06 (0.07) -0.06 (0.07)
Gender (girl = 1) -0.33*** (0.05) -0.33*** (0.05)
Phonology*Time -0.10*** (0.02)
Between-individuals
variance
2.76 0.78 0.77
Within-individuals
variance
1.99 2.00 2.00
Log-likelihood -12349.43 -11263.05 -11255.167
LR test (Δdf) 15.76*** (1)
*** p < .001, ** p < .01, * p < .05
The results revealed that phonological ability had a positive effect on math achievement.
The effect was significant even controlling for reading achievement and number identification.
There was a significant difference in math achievement regarding maternal education: the
students from families where the mother had higher education had higher math achievement. The
number of books at home and language at home had no effect on math achievement.
In Model 3, the interaction between phonological ability and the time variable was
significant and negative. This indicated that time changes in math achievement were higher for
children with low phonological ability. Math achievement at Time 1 was higher for students with
high phonological ability, so difference in math achievements for students with high and low
phonological ability reduced at Time 2 (Figure 1).
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Figure 1. Time changes in math achievement for students with different phonological ability
Further analysis revealed that time changes in math achievement significantly varied for students
with different SES background (Table 4).
Table 4
The results of mixed-effect analysis for math achievement as outcome and interaction with SES
Variables Model 4 Model 5 Model 6
Constant -1.79*** (0.08) -1.85*** (0.07) -1.76*** (0.09)
Time 0.92*** (0.06) 1.04*** (0.05) 0.86*** (0.10)
Phonological ability 0.19*** (0.02) 0.19*** (0.02) 0.19*** (0.02)
Reading achievement 0.16*** (0.01) 0.16*** (0.01) 0.16*** (0.01)
Number identification 0.19*** (0.01) 0.19*** (0.01) 0.19*** (0.01)
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Mother has higher
education
0.19** (0.06) 0.30*** (0.05) 0.30*** (0.05)
Number of books at home 0.11 (0.08) 0.14 (0.10) 0.11 (0.08)
Only Russian language at
home
-0.06 (0.07) -0.06 (0.07) -0.16 (0.08)
Gender (girl = 1) -0.33*** (0.05) -0.33*** (0.05) -0.33*** (0.05)
Interaction effect
Mother’s education*Time 0.22** (0.07)
Book at home*Time -0.05 (0.11)
Language at home*Time 0.21* (0.10)
Random effect
Between-individuals
variance
0.78 0.78 0.78
Within-individuals
variance
1.99 2.00 2.00
Log-likelihood -11258.65 -11262.93 -11260.83
LR test (Δdf) 8.80** (1) 0.23 (1) 4.44* (1)
*** p < .001, ** p < .01, * p < .05
These results demonstrated that progress in math was greater for pupils with more highly
educated mothers. Education-related differences in math achievement increased from the
beginning to the end of the first grade (Figure 2).
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Figure 2. Time changes in math achievement for students with different levels of mother’s
education
The number of books at home had no effect on math achievement or development in math.
There was no significant difference between students at the beginning and at the end of the first
grade depending on language at home, although time changes in math were larger for students
who used only Russian at home (Figure 3).
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Figure 3. Time changes in math achievement for students with different language background
Table 5 shows the estimation of the effect of phonological ability for students with different
SES.
Table 5
The results of mixed-effect analysis for math achievement as outcome and interaction with SES
Variables Model 7 Model 8 Model 9
Constant -1.85*** (0.08) -1.83*** (0.07) -1.95*** (0.08)
Time 1.04*** (0.04) 1.03*** (0.04) 1.03*** (0.04)
Phonological ability 0.19*** (0.02) 0.18*** (0.02) 0.27*** (0.03)
Reading achievement 0.16*** (0.01) 0.16*** (0.01) 0.16*** (0.01)
Number identification 0.19*** (0.01) 0.19*** (0.01) 0.19*** (0.01)
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Mother has higher
education
0.30*** (0.05) 0.30*** (0.05) 0.30*** (0.05)
Number of books at home 0.11 (0.08) -0.04 (0.10) 0.12 (0.07)
Only Russian language at
home
-0.06 (0.07) -0.06 (0.07) 0.06 (0.08)
Gender (girl = 1) -0.33*** (0.05) -0.33*** (0.05) -0.33*** (0.05)
Interaction effect
Mother’s education*
Phonology
0.002 (0.03)
Book at home*Phonology 0.09* (0.04)
Language at home*
Phonology
-0.09* (0.04)
Random effect
Between-individuals
variance
0.78 0.78 0.78
Within-individuals
variance
2.00 2.00 2.00
Log-likelihood -11263.04 -11259.79 -11259.99
LR test (Δdf) 0.01 (1) 6.51* (1) 6.13* (1)
*** p < .001, ** p < .01, * p < .05
Models with interaction revealed that maternal education did not moderate the effect of
phonological ability on math achievement. The number of books at home significantly
moderated the effect of phonological ability on math. A simple slope analysis revealed that the
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effect was higher for children with more than 100 books at home (Table 6). The interaction
between phonological ability and language at home was significant and negative. This indicated
that the effect of phonological ability was lower for children from families that used only
Russian at home compared to children from families using another language at home (Table 6).
Table 6.
The effect of phonological ability on math achievement for students with different number of
books and language at home
Indicators of SES The effect of phonological ability 95% CI
Less than 100 books at home 0.18*** (0.02) 0.15; 0.21
More than 100 books at home 0.27*** (0.04) 0.20; 0.34
Not only Russian language at home 0.27*** (0.03) 0.20; 0.34
Only Russian language at home 0.18*** (0.02) 0.15; 0.21
*** p < .001
These results revealed that phonological ability had an effect on math achievement but the effect
depended on SES. On the other hand, there were no differences in math achievement for children
depending on the number of books at home for low and medium levels of phonological ability
whereas children with more than 100 books at home outperformed children with a small number
of books at home at high levels of phonological ability (Figure 4).
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Figure 4. The effect of phonological ability on math achievement for children with different
number of books at home
At high levels of phonological ability, children with another language at home outperform
children who used only Russian at home (Figures 5).
Figure 5. The effect of phonological ability on math achievement for children with different
language background
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Discussion
Previous studies show contradictory results regarding the effect of phonological ability on
math achievement. Although some psychophysiological studies revealed that SES modulated the
relationship between the activation of language brain areas and math problem solving, there are
no studies that demonstrate that the effect of phonological ability varies for students from
different SES backgrounds. Our study filled that gap.
We used a large sample of first-graders who participated in iPIPS and were tested twice: at
the beginning and at the end of the first grade. The two-wave longitudinal design allowed us to
estimate if the changes in phonological ability related to changes in math achievement using
mixed-effect models. We also controlled for SES which was measured by maternal education,
the number of books at home and language at home.
Our study had three main findings. First, we found that phonological ability affected
math achievement even when reading achievement and early precursors of math achievement
such as number identification skills were controlled for. Several studies demonstrated that
phonological ability did not directly predict math achievement. They show that phonological
ability uniquely predict reading achievement and, in turn, poor reading skills might be related to
low math achievement (Bradley & Bryant, 1983; Passolunghi, Vercelloni & Schadee, 2007). Our
results revealed that both phonological ability and reading achievement predicted math
achievement.
Our results also demonstrated that improvement in math achievement during the first
year of schooling was higher for children with low levels of phonological ability. These results
might be unexpected but it should be taken into account that children with high phonological
ability had a significantly higher math achievement at the start of schooling. This smaller
progress might be explained by high achievement at the start and the ceiling effect at the end of
the school year.
Second, we found that some indicators of SES affect math achievement and math growth.
Previous studies demonstrated that maternal education was a powerful predictor of academic
achievement (Hoff, 2006; Hoff, Laursen, & Bridges, 2012). Our analysis revealed that children
with a more educated mother had higher math achievement and larger improvement in math.
Parental education affects academic performance in different ways. First, more educated parents
can directly provide resources at home for more successful education, both material and non-
material (Bradley & Corwyn, 2002). Secondly, parents with a lower level of education may pay
less attention to academic achievement and have lower educational expectations which may lead
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to lower performance and less progress (e.g. Davis-Kean, 2005; Englund et al., 2004; Zady &
Portes, 2001).
Third, although the number of books at home and language at home did not affect math
achievement directly, they might modulate the relationship between phonological ability and
math. Particularly, phonological ability had a larger effect on math achievement for children
with a larger number of books at home. The number of books at home might be considered an
indicator of family cultural capital (Brunello, Weber, & Weiss, 2016) and be related to the
amount of verbal interaction within the family, frequencies of reading or other verbal activity
(Hart & Risley, 1995; Weigel, Martin, & Bennett, 2006). During their development children
from families with higher cultural capital might learn to better manipulate verbal representations
in general and the verbal representation of numbers specifically (comparing to lower SES
children. As a consequence, high SES students may more often recruit phonological processing
during math problem solving.
Sixteen percent of participants in our study used another language at home,
predominantly Tatar. Although instruction at school was in Russian, some pupils used Tatar at
home, so these students were bilingual. There were contradictory results regarding the
differences in academic achievement and phonological ability in bilingual children (Bialystok,
Majumder, & Martin, 2003; Chen et al., 2004; Mouw &Xie, 1999). Some studies demonstrate
that bilingual students have a higher level of phonological ability (Kang, 2012; Loizou & Stuart,
2003). Our study demonstrated that bilingual first-graders did not have significantly lower math
achievement at the start and at the end of the first grade. Additional analysis revealed that
students did not differ in phonological ability depending on language background. The effect of
phonological ability was greater for bilingual students. Probably, bilingual students also recruit
phonological resources more often during math problem solving.
It should be noted that phonological ability was measured for the Russian language
although for bilingual students phonological ability might be measured for both languages.
Previously, it was demonstrated that the consistency between spelling and sounds in a language
might affect children’s phonological skills and the relationship between phonological and
reading skills (Landerl & Wimmer, 2008). As an example, languages with more inconsistent
spelling-sound correspondence, such as English, show a longer and larger effect of phonological
ability on reading (e.g., Torgesen, Wagner, Rashotte, & Burgess, 1997). A similar effect could
likely be observed regarding math performance. In our study, we use the Russian language,
which represents a group of Slavic languages and uses the Cyrillic alphabet. Russian phonology
has several specific characteristics, which include non-systematic stress patterns, some forms of
vowel reduction and consonant assimilation, complex syllable structure. In other words, Russian
22
has been suggested to be in the middle of the continuum, between more regularly spelled
languages, for example, Finnish, and English (Laurinavichyute et al., 2018; Seymour et al.,
2003). Results may change for bilingual children if phonological ability is measured in both
languages.
Our study has some limitations. First, we were able to use only a two-wave longitudinal
design. However, it would no doubt be better to have three or more waves in the study in order
to more precisely estimate the relationships between our key variables. Another important
limitation was the nature of the indicators we used as phonological ability constructs.
Phonological ability is represented in this study mostly by one dimension instead of the possible
three. Future studies would benefit from having more items measuring lexical access,
phonological awareness and memory. Using mixed-effect models did not solve the problems of
omitted variables. We estimated the effect of both time-variant and time-invariant variables but
we did not control for a large number of possible predictors of math achievement that potentially
may explain the correlation between phonological ability and math achievement such as
intelligence or executive functions. Future studies are necessary to disentangle the effect of
phonological ability from the effect of other cognitive functions.
The results of our study have several practical implications. First, to improve
mathematics achievement, some interventions or remedial instruction in the first grade of
schooling could be considered. Our results demonstrate that phonological skills should be taken
into account when planning interventions to improve mathematical achievement. Second,
parental mathematical activities at home should not only focus on promoting children’s basic
mathematics skills such as digit knowledge or basic arithmetic but also be accompanied by some
sort of phonological activities. Third, the effect of phonological ability varies depending on
family SES, meaning that children with low SES were less likely to recruit phonological
resources for math problem solving. Therefore, in planning the training programs for low SES
children it could be beneficial to use less verbal instructions and more graphical, visual
representations of math concepts and tasks. The presentation of math tasks in different formats,
verbal and visual, could reduce SES-related difference in math, at least, in elementary school.
23
Reference:
Ardila, A., Rosselli, M., Matute, E., & Guajardo, S. (2005). The influence of the parents'
educational level on the development of executive functions. Developmental
neuropsychology, 28(1), 539-560.
Arsalidou, M., & Taylor, M. J. (2011). Is 2+ 2= 4? Meta-analyses of brain areas needed for
numbers and calculations. Neuroimage, 54(3), 2382-2393.
Bialystok, E., Majumder, S., & Martin, M. M. (2003). Developing phonological
awareness: Is there a bilingual advantage?. Applied Psycholinguistics, 24(1), 27-44.
Bowey, J. A. (1995). Socioeconomic status differences in preschool phonological
sensitivity and first-grade reading achievement. Journal of educational Psychology, 87(3), 476.
Bradley, L., & Bryant, P. E. (1983). Categorizing sounds and learning to read—a causal
connection. Nature, 301(5899), 419.
Bradley, R. H., & Corwyn, R. F. (2002). Socioeconomic status and child
development. Annual review of psychology, 53(1), 371-399.
Brunello, G., Weber, G., & Weiss, C. T. (2016). Books are forever: Early life conditions,
education and lifetime earnings in Europe. The Economic Journal, 127(600), 271-296.
Brunello, G., Weber, G., & Weiss, C. T. (2016). Books are forever: Early life conditions,
education and lifetime earnings in Europe. The Economic Journal, 127(600), 271-296.
Caro, D., McDonald, T., & Willms, J. D. (2009). A longitudinal analysis of math
achievement gaps associated with socio-economic status: How do they change from childhood to
adolescence. Manuscript submitted for publication.
Chen, X., Anderson, R. C., Li, W., Hao, M., Wu, X., & Shu, H. (2004). Phonological
awareness of bilingual and monolingual Chinese children. Journal of Educational
Psychology, 96(1), 142.
Chiu, M. M., & Xihua, Z. (2008). Family and motivation effects on mathematics
achievement: Analyses of students in 41 countries. Learning and Instruction, 18(4), 321-336.
Davis-Kean, P. E. (2005). The influence of parent education and family income on child
achievement: the indirect role of parental expectations and the home environment. Journal of
family psychology, 19(2), 294.
24
de Jong, P. F., & van der Leij, A. (1999). Specific contributions of phonological abilities to
early reading acquisition: Results from a Dutch latent variable longitudinal study. Journal of
Educational psychology, 91(3), 450.
De Smedt, B. (2018). Language and Arithmetic: The Potential Role of Phonological
Processing. In Heterogeneity of Function in Numerical Cognition (pp. 51-74).
De Smedt, B., & Boets, B. (2010). Phonological processing and arithmetic fact retrieval:
evidence from developmental dyslexia. Neuropsychologia, 48(14), 3973-3981.
De Smedt, B., Taylor, J., Archibald, L., & Ansari, D. (2010). How is phonological
processing related to individual differences in children’s arithmetic skills?. Developmental
science, 13(3), 508-520.
Demir, Ö. E., Prado, J., & Booth, J. R. (2015). Parental socioeconomic status and the
neural basis of arithmetic: differential relations to verbal and visuo‐spatial
representations. Developmental science, 18(5), 799-814.
Demir-Lira, Ö. E., Prado, J., & Booth, J. R. (2016). Neural correlates of math gains vary
depending on parental socioeconomic status (SES). Frontiers in psychology, 7, 892.
Engel, P. M. J., Santos, F. H., & Gathercole, S. E. (2008). Are working memory measures
free of socioeconomic influence?. Journal of Speech, Language, and Hearing Research, 51(6),
1580-1587.
Englund, M. M., Luckner, A. E., Whaley, G. J., & Egeland, B. (2004). Children's
achievement in early elementary school: Longitudinal effects of parental involvement,
expectations, and quality of assistance. Journal of Educational Psychology, 96(4), 723.
Evans, M. D., Kelley, J., Sikora, J., & Treiman, D. J. (2010). Family scholarly culture and
educational success: Books and schooling in 27 nations. Research in social stratification and
mobility, 28(2), 171-197.
Farah, M. J., Shera, D. M., Savage, J. H., Betancourt, L., Giannetta, J. M., Brodsky, N. L.,
... & Hurt, H. (2006). Childhood poverty: Specific associations with neurocognitive
development. Brain research, 1110(1), 166-174.
Geary, D. C. (1993). Mathematical disabilities: Cognitive, neuropsychological, and genetic
components. Psychological bulletin, 114(2), 345.
25
Hackman, D. A., Gallop, R., Evans, G. W., & Farah, M. J. (2015). Socioeconomic status
and executive function: Developmental trajectories and mediation. Developmental
Science, 18(5), 686-702.
Hart, B., & Risley, T. R. (1995). Meaningful differences in the everyday experience of
young American children. Paul H Brookes Publishing.
Hecht, S. A., Burgess, S. R., Torgesen, J. K., Wagner, R. K., & Rashotte, C. A. (2000).
Explaining social class differences in growth of reading skills from beginning kindergarten
through fourth-grade: The role of phonological awareness, rate of access, and print
knowledge. Reading and writing, 12(1-2), 99-128.
Hoff, E. (2006). How social contexts support and shape language
development. Developmental review, 26(1), 55-88.
Hoff, E., Laursen, B., & Bridges, K. (2012). Measurement and model building in studying
the influence of socioeconomic status on child development. The Cambridge handbook of
environment in human development, 590-606.
Ivanova, A., Kardanova, E., Merrell, C., Tymms, P., & Hawker, D. (2018). Checking the
possibility of equating a mathematics assessment between Russia, Scotland and England for
children starting school. Assessment in Education: Principles, Policy & Practice, 25(2), 141-
159.
Joanisse, M. F., Manis, F. R., Keating, P., & Seidenberg, M. S. (2000). Language deficits
in dyslexic children: Speech perception, phonology, and morphology. Journal of experimental
child psychology, 77(1), 30-60.
Jordan, N. C., & Levine, S. C. (2009). Socioeconomic variation, number competence, and
mathematics learning difficulties in young children. Developmental disabilities research
reviews, 15(1), 60-68.
Jordan, N. C., Kaplan, D., Locuniak, M. N., & Ramineni, C. (2007). Predicting first‐grade
math achievement from developmental number sense trajectories. Learning Disabilities
Research & Practice, 22(1), 36-46.
Jordan, N. C., Kaplan, D., Nabors Oláh, L., & Locuniak, M. N. (2006). Number sense
growth in kindergarten: A longitudinal investigation of children at risk for mathematics
difficulties. Child development, 77(1), 153-175.
26
Kang, J. Y. (2012). Do bilingual children possess better phonological awareness?
Investigation of Korean monolingual and Korean-English bilingual children. Reading and
Writing, 25(2), 411-431.
Kennedy, E., & Park, H. S. (1994). Home language as a predictor of academic
achievement: A comparative study of Mexican-and Asian-American youth. Journal of Research
& Development in Education.
Kolen, M. J., & Brennan, R. L. (2004). Test equating, scaling, and linking.
Landerl, K., & Wimmer, H. (2008). Development of word reading fluency and spelling in
a consistent orthography: an 8-year follow-up. Journal of educational psychology, 100(1), 150.
Landerl, K., Bevan, A., & Butterworth, B. (2004). Developmental dyscalculia and basic
numerical capacities: A study of 8–9-year-old students. Cognition, 93(2), 99-125.
Laurinavichyute, A. K., Sekerina, I. A., Alexeeva, S., Bagdasaryan, K., & Kliegl, R.
(2018). Russian Sentence Corpus: Benchmark measures of eye movements in reading in
Russian. Behavior research methods, 1-18.
Loizou, M., & Stuart, M. (2003). Phonological awareness in monolingual and bilingual
English and Greek five‐year‐olds. Journal of Research in Reading, 26(1), 3-18.
Melby-Lervåg, M., Lyster, S. A. H., & Hulme, C. (2012). Phonological skills and their role
in learning to read: a meta-analytic review. Psychological bulletin, 138(2), 322.
Molfese, V. J., Modglin, A., & Molfese, D. L. (2003). The role of environment in the
development of reading skills: A longitudinal study of preschool and school-age
measures. Journal of learning disabilities, 36(1), 59-67.
Moll, K., Göbel, S. M., & Snowling, M. J. (2015). Basic number processing in children
with specific learning disorders: Comorbidity of reading and mathematics disorders. Child
neuropsychology, 21(3), 399-417.
Mouw, T., & Xie, Y. (1999). Bilingualism and the academic achievement of first-and
second-generation Asian Americans: accommodation with or without assimilation?. American
sociological review, 232-252.
Noble, K. G., Farah, M. J., & McCandliss, B. D. (2006). Socioeconomic background
modulates cognition–achievement relationships in reading. Cognitive Development, 21(3), 349-
368.
27
Noble, K. G., Wolmetz, M. E., Ochs, L. G., Farah, M. J., & McCandliss, B. D. (2006).
Brain–behavior relationships in reading acquisition are modulated by socioeconomic
factors. Developmental science, 9(6), 642-654.
OECD (2010). PISA 2009 Results: What Students Know and Can Do – Student
Performance in Reading, Mathematics and Science (Volume I)
http://dx.doi.org/10.1787/9789264091450-en
Passolunghi, M. C., Vercelloni, B., & Schadee, H. (2007). The precursors of mathematics
learning: Working memory, phonological ability and numerical competence. Cognitive
Development, 22(2), 165-184.
Pollack, C., & Ashby, N. C. (2018). Where arithmetic and phonology meet: The meta-
analytic convergence of arithmetic and phonological processing in the brain. Developmental
cognitive neuroscience, 30, 251-264.
Polspoel, B., Peters, L., Vandermosten, M., & De Smedt, B. (2017). Strategy over
operation: neural activation in subtraction and multiplication during fact retrieval and procedural
strategy use in children. Human brain mapping, 38(9), 4657-4670.
Prado, J., Mutreja, R., & Booth, J. R. (2014). Developmental dissociation in the neural
responses to simple multiplication and subtraction problems. Developmental science, 17(4), 537-
552.
Prado, J., Mutreja, R., Zhang, H., Mehta, R., Desroches, A. S., Minas, J. E., & Booth, J. R.
(2011). Distinct representations of subtraction and multiplication in the neural systems for
numerosity and language. Human brain mapping, 32(11), 1932-1947.
Ramus, F., Rosen, S., Dakin, S. C., Day, B. L., Castellote, J. M., White, S., & Frith, U.
(2003). Theories of developmental dyslexia: insights from a multiple case study of dyslexic
adults. Brain, 126(4), 841-865.
Rourke, B. P., & Conway, J. A. (1997). Disabilities of arithmetic and mathematical
reasoning: Perspectives from neurology and neuropsychology. Journal of Learning
disabilities, 30(1), 34-46.
Seymour, P. H., Aro, M., Erskine, J. M., & collaboration with COST Action A8 network.
(2003). Foundation literacy acquisition in European orthographies. British Journal of
psychology, 94(2), 143-174.
28
Simon, O., Mangin, J. F., Cohen, L., Le Bihan, D., & Dehaene, S. (2002). Topographical
layout of hand, eye, calculation, and language-related areas in the human parietal
lobe. Neuron, 33(3), 475-487.
Sirin, S. R. (2005). Socioeconomic status and academic achievement: A meta-analytic
review of research. Review of educational research, 75(3), 417-453.
Torgesen, J. K., Wagner, R. K., Rashotte, C. A., Burgess, S., & Hecht, S. (1997).
Contributions of phonological awareness and rapid automatic naming ability to the growth of
word-reading skills in second-to fifth-grade children. Scientific studies of reading, 1(2), 161-185.
Tymms, P. (1999). Baseline assessment, value‐added and the prediction of
reading. Journal of Research in Reading, 22(1), 27-36.
Tymms, P., Merrell, C., & Wildy, H. (2015). The progress of pupils in their first school
year across classes and educational systems. British Educational Research Journal, 41(3), 365-
380.
Valle-Lisboa, J., Cabana, Á., Eisinger, R., Mailhos, Á., Luzardo, M., Halberda, J., &
Maiche, A. (2016). Cognitive abilities that mediate SES’s effect on elementary mathematics
learning: The Uruguayan tablet-based intervention. Prospects, 46(2), 301-315.
Vanbinst, K., Ghesquière, P., & De Smedt, B. (2014). Arithmetic strategy development
and its domain-specific and domain-general cognitive correlates: A longitudinal study in
children with persistent mathematical learning difficulties. Research in developmental
disabilities, 35(11), 3001-3013.
Vukovic, R. K., & Siegel, L. S. (2010). Academic and cognitive characteristics of
persistent mathematics difficulty from first through fourth grade. Learning Disabilities Research
& Practice, 25(1), 25-38.
Wagner, R. K., & Torgesen, J. K. (1987). The nature of phonological processing and its
causal role in the acquisition of reading skills. Psychological bulletin, 101(2), 192.
Weigel, D. J., Martin, S. S., & Bennett, K. K. (2006). Contributions of the home literacy
environment to preschool‐aged children’s emerging literacy and language skills. Early Child
Development and Care, 176(3-4), 357-378
Zady, M. F., & Portes, P. R. (2001). When low-SES parents cannot assist their children in
solving science problems. Journal of Education for Students Placed at Risk, 6(3), 215-229.
29
Zhang, Y., Tardif, T., Shu, H., Li, H., Liu, H., McBride-Chang, C., ... & Zhang, Z. (2013).
Phonological skills and vocabulary knowledge mediate socioeconomic status effects in
predicting reading outcomes for Chinese children. Developmental psychology, 49(4), 665.
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Yulia V. Kuzmina
Center of Education Quality Monitoring, Institute of Education, National Research University
Higher School of Economics, research fellow, e-mail ([email protected])
Any opinions or claims contained in this Working Paper do not necessarily reflect the
views of НSE.
©Kuzmina, Kaiky, Ivanova, 2018
.